Software Engineer for flight simulators & other ground based training systems. Until April 2018: Security Officer, Software & Quality Engineer for Cisco Kinetic. Distinguished Contributor at OASIS, Python Software Foundation & Erlang Ecosystem Foundation member.
Likes: | people python-3.x elixir go c++17 bash ecmascript-2017 |
Dislikes: | php |
Support department wide software development through peer reviews, actionable agile metrics, coaching and tool creation.
Support software development life cycle, quality management, peer reviews, coaching and tool creation.
Focus on security, software, and quality engineering components of the Cisco platform for the Internet of Things: Kinetic
Head of Quality Assurance. Designed and implemented the System Test Framework and Li- brary. Lead project to bridge System Test Framework and Library to the Robot-Framework. Test Design, implementation and execution of system tests to assure the sustained quality of the ParStream Analytics Platform.
ParStream has been acquired by Cisco.
Working with the people there and really getting into programming, data analysis and tcp/ip technology
This document defines JSON and XML based request/response protocols for signing and verifying documents and other data. It also defines a timestamp format, and a signature property for use with these protocols. Finally, it defines transport and security bindings for the protocols.
Contributed as Editor
Andreas Kuehne (Ed.) and Stefan Hagen (Ed.), “Digital Signature Service Core Protocols, Elements, and Bindings” Version 2.0, OASIS Committee Specification Draft 03 / Public Review Draft 03, 11 September 2019
This document defines a standard format for the output of static analysis tools. The format is referred to as the “Static Analysis Results Interchange Format” and is abbreviated as SARIF
Contributed as TC member
Static Analysis Results Interchange Format (SARIF) Version 2.0. Edited by Michael Fanning and Laurence J. Golding. 15 June 2018. OASIS Committee Specification Draft 01/Public Review Draft 01. http://docs.oasis-open.org/sarif/sarif/v2.0/csprd01/sarif-v2.0-csprd01.html. Latest version: http://docs.oasis-open.org/sarif/sarif/v2.0/sarif-v2.0.html.
MQTT is a Client Server publish/subscribe messaging transport protocol. It is light weight, open, simple, and designed to be easy to implement. These characteristics make it ideal for use in many situations, including constrained environments such as for communication in Machine to Machine (M2M) and Internet of Things (IoT) contexts where a small code footprint is required and/or network bandwidth is at a premium. The protocol runs over TCP/IP, or over other network protocols that provide ordered, lossless, bi-directional connections. Its features include: · Use of the publish/subscribe message pattern which provides one-to-many message distribution and decoupling of applications. · A messaging transport that is agnostic to the content of the payload. · Three qualities of service for message delivery: o "At most once", where messages are delivered according to the best efforts of the operating environment. Message loss can occur. This level could be used, for example, with ambient sensor data where it does not matter if an individual reading is lost as the next one will be published soon after. o "At least once", where messages are assured to arrive but duplicates can occur. o "Exactly once", where messages are assured to arrive exactly once. This level could be used, for example, with billing systems where duplicate or lost messages could lead to incorrect charges being applied. · A small transport overhead and protocol exchanges minimized to reduce network traffic. · A mechanism to notify interested parties when an abnormal disconnection occurs.
Contributed as TC member
MQTT Version 5.0. Edited by Andrew Banks, Ed Briggs, Ken Borgendale, and Rahul Gupta. 15 May 2018. OASIS Committee Specification 02. http://docs.oasis-open.org/mqtt/mqtt/v5.0/cs02/mqtt-v5.0-cs02.html. Latest version: http://docs.oasis-open.org/mqtt/mqtt/v5.0/mqtt-v5.0.html.
The CSAF Common Vulnerability Reporting Framework (CVRF) Version 1.2 is the definitive reference for the CSAF CVRF language which supports creation, update, and interoperable exchange of security advisories as structured information on products, vulnerabilities and the status of impact and remediation among interested parties.
CSAF Common Vulnerability Reporting Framework (CVRF) Version 1.2. Edited by Stefan Hagen. 13 September 2017. OASIS Committee Specification 01. http://docs.oasis-open.org/csaf/csaf-cvrf/v1.2/cs01/csaf-cvrf-v1.2-cs01.html. Latest version: http://docs.oasis-open.org/csaf/csaf-cvrf/v1.2/csaf-cvrf-v1.2.html.
This document describes the shape of, and motivation behind, the changes in OData Version 4.01 compared to its predecessor version 4.0.
What’s New in OData Version 4.01. Edited by Ralf Handl, Mike Pizzo, Stefan Hagen , and Martin Zurmuehl. 08 June 2017. OASIS Committee Note 01. http://docs.oasis-open.org/odata/new-in-odata/v4.01/cn01/new-in-odata-v4.01-cn01.html. Latest version: http://docs.oasis-open.org/odata/new-in-odata/v4.01/new-in-odata-v4.01.html.
Butler, H., Daly, M., Doyle, A., Gillies, S., Hagen, S., and T. Schaub, "The GeoJSON Format", RFC 7946, DOI 10.17487/RFC7946, August 2016, https://www.rfc-editor.org/info/rfc7946.
GeoJSON is a geospatial data interchange format based on JavaScript Object Notation (JSON). It defines several types of JSON objects and the manner in which they are combined to represent data about geographic features, their properties, and their spatial extents. GeoJSON uses a geographic coordinate reference system, World Geodetic System 1984, and units of decimal degrees.
This document describes how OData Version 4.0 differs from its predecessor version, and why.
What’s New in OData Version 4.0. 15 August 2013. OASIS Committee Note 01. http://docs.oasis-open.org/odata/new-in-odata/v4.0/cn01/new-in-odata-v4.0-cn01.html.
This document defines XML request/response protocols for signing and verifying XML documents and other data. It also defines an XML timestamp format, and an XML signature property for use with these protocols. Finally, it defines transport and security bindings for the protocols.
Contributed as Editor
Stefan Drees et al., “Digital Signature Service Core Protocols, Elements, and Bindings” Version 1.0, OASIS Standard, 11 April 2007
Time-of-flight charge state spectra of Xe have been obtained after photoionisation at energies from 4keV to 8keV (L-edges). The measurements were carried out at the beamline BN0 of ELSA (Electron Stretcher and Accelerator) in Bonn, using the tunable, monoenergetic synchro- tron light of a double-crystal-monochromator (Ge(220),∆E ≈ 1.5 eV ). The relative abundances of the ionic charge states Xe7+ and Xe8+ were found to increase si- gnificantly well below the L3-edge. The relative production cross sections were obtained by multiplying the relative abundances of the ionic charge states with the total ion flux recorded separately, i.e. the total photoionisation cross section. The effective photon flux was monitored by recording the total photoelectron yield from a Be-target and the total ion yield of a nitrogen filled ionisation chamber. The monitors were successfully tested and revealed irregularities in the monoenergetic photon flux as a function of the circulating electron current. The time-of-flight spectrometer has been studied by means of a 2-dimensional grid-model im- plemented in the software-packageToFModel. The influence of field distortions in the spec- trometer upon the observed line shapes has been examined with the help of other software tools.
[dnp entry at: http://d-nb.info/931622190]
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First Computer: | Commodore PC-10 |
Favorite Editor: | Eight Megabytes And Constantly Swapping |